Periodic optical filter stabilized tunable comb generator

ABSTRACT

A tunable electro-optic modulation (EOM) comb generator includes a frequency locking optoelectronic oscillator (OEO) loop including RF electrical components including a phase shifter (PS1), a splitter, and optical components including an intensity modulator (IM) coupled to receive light from a light source and to couple modulated light generated to a frequency locking loop including a frequency shifter, a first phase modulator (PM1), and a periodic optical filter (POF), such as an etalon or resonator. The POF is for optically filtering the OEO loop to generate an optical output and the splitter is for generating RF electrical outputs including at least one RF output coupled to an input of the IM and another RF output coupled to an EO comb including at least a phase modulator. The EO comb combines the optical output and the another RF output to generate a broadband optical frequency comb output.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of Provisional Application Ser. No.62/639,330 entitled “ETALON STABILIZED AND FILTERED TUNABLE COMBGENERATOR”, filed on Mar. 6, 2018, which is herein incorporated byreference in its entirety.

U.S. GOVERNMENT RIGHTS

This invention was made with U.S. Government support under NationalScience Foundation (NSF) Award #1059619 awarded by the Defense AdvancedResearch Projects Agency (DARPA) under the DARPA—Direct On-chip DigitalOptical Synthesizer (DODOS) Program. The Government has certain rightsin this invention.

FIELD

This Disclosure relates to electro-optic (EO) comb generators.

BACKGROUND

An EO comb generator (EO comb) is a type of signal generator whichgenerates multiple harmonics of its received optical input signal whichprovides an output spectrum which resembles the teeth of a comb. Seedsources used by such EO combs include mode-locked lasers (MLLs),optically pumped micro ring resonators, and the electro-optic modulationof a narrow linewidth continuous wave (CW) laser. In the CW laser casean electrical signal from a high frequency oscillator is applied toseries of EO phase and intensity modulators to generate sidebands arounda single CW tone from the laser, generating coherent optical combsgenerally spanning several nanometers in width.

In the simplest case an EO modulation (EOM) comb can be configured usingcommercially available components including a CW laser, intensity andphase modulators, and an external high frequency RF source for providinga high-frequency RF driving signal. Such EOM combs have generally beenused for the generation of ultrashort optical pulses. More recently EOMcombs have seen more frequent use as an optical source for a broaderscope of applications, such as for molecular spectroscopy and foroptical frequency synthesis.

SUMMARY

This Summary is provided to introduce a brief selection of disclosedconcepts in a simplified form that are further described below in theDetailed Description including the drawings provided. This Summary isnot intended to limit the claimed subject matter's scope.

Disclosed aspects include an optoelectronic oscillator (OEO) driventunable EOM comb generator whose oscillation frequency and comb toothspacing are defined by the narrow resonance of a periodic optical filter(POF), such as a Fabry Pérot etalon (FPE) or a high finesse resonator,not by conventional electronic filtering. The FPE is generally a highfinesse FPE. The OEO loop output is optically filtered by the POF. Asknown in the art, the finesse for a POF such as for an FPE is defined asthe ratio of the free spectral range (FSR) to the full width halfmaximum of the transmission peaks. The term ‘high finesse’ as usedherein refers to a finesse value of at least 1,000, such as being 10,000to 100,000.

Optical and radio frequency (RF) electrical outputs of the OEO loop arecombined by at least one phase modulators (PM) of an EOM comb togenerate a spectrally flat, broadband EOM comb output. The EOM comb caninclude one PM, 2 PMs or 3 (or more) PMs, wherein each of thesearrangements generate a similar optical output, with the only differencegenerally being the output optical bandwidth may decrease (for one PM)or increase (for 3 PMs) relative to the 2 PM EOM comb.

Adjustment of a variable delay (e.g., using a phase shifter) within theOEO loop allows for tuning of output combline spacing to harmonics ofthe POF's FSR that fall within the electrical bandwidth of the RFcomponents of the OEO. Disclosed EOM comb generators are believed toprovide unique advantages including a POF that provides highly selectivefiltering, enhanced OEO frequency stability and narrowing of comb toothlinewidths. Incorporating PMs in the EOM comb, thus outside of the OEOloop, allows for independently tuning of the EOM comb's spectral phasefor ultrashort pulse generation without affecting oscillation.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A shows an example tunable EOM comb generator embodied as a1-phase modulator, according to a disclosed embodiment.

FIG. 1B shows an example tunable EOM comb generator embodied as a2-phase modulator, according to a disclosed embodiment.

FIG. 1C shows an example tunable EOM comb generator embodied as a3-phase modulator, according to a disclosed embodiment.

FIG. 2A shows a heterodyne beat of a CW laser with a commercial 100 Hzlinewidth laser, showing a significant linewidth reduction as a directconsequence of disclosed frequency locking to the FPE. FIG. 2B shows theheterodyne beat in FIG. 2A plotted with overlaid Lorentzians of 450 HzFWHM (L1) and 200 Hz FWHM (L2).

FIG. 3A shows overlaid output RF spectra showing single-mode OEOoperation at frequencies of 7.5, 9, 10.5 and 12 GHz. Spectra weremeasured after 20 dB of attenuation. Frequency tuning is achieved byadjusting an RF phase shifter in the OEO loop (see PS1 134 in FIGS.1A-1C). FIG. 3B shows a close-span spectrum of an OEO generated RF toneat 10.5 GHz with (the x-axis showing the frequency offset (in kHz).Characteristics of this RF tone are typical for all OEO operationfrequencies disclosed herein.

FIG. 4 shows fractional frequency stability of an RF tone operating at10.5 GHz. Allan deviation (shown as ADEV) is measured as low as 5×10⁻¹⁰at τ=0.2 seconds. Also plotted is the Allan deviation of thecorresponding EOM comb's photodetected pulse train, showing that the EOMcomb ‘inherits’ the stability of the OEO loop.

FIG. 5 is an optical spectrum showing an example average EOM comb outputpower monitored every five minutes for over an hour, with error barsshowing the standard deviation of the comb tooth amplitude. The x-axisis in nms.

FIGS. 6A-6D show the optical spectra provided by a disclosed EOM combgenerator generated showing 7.5, 9, 10.5 and 12 GHz spacings,respectively. The x-axis is the wavelength in nms.

FIG. 7 shows intensity autocorrelation of an output pulse from adisclosed EOM comb generator after 600 m of fiber is included, showingan autocorrelation (AC) pulse width of 2.6 psec (curve 1). Also plottedis the Fourier transform limit pulse (curve 2), calculated using theoptical spectrum and assuming a flat phase.

DETAILED DESCRIPTION

Disclosed embodiments are described with reference to the attachedfigures, wherein like reference numerals, are used throughout thefigures to designate similar or equivalent elements. The figures are notdrawn to scale and they are provided merely to illustrate aspectsdisclosed herein. Several disclosed aspects are described below withreference to example applications for illustration. It should beunderstood that numerous specific details, relationships, and methodsare set forth to provide a full understanding of the embodimentsdisclosed herein.

Notwithstanding that the numerical ranges and parameters setting forththe broad scope of this Disclosure are approximations, the numericalvalues set forth in the specific examples are reported as precisely aspossible. Any numerical value, however, inherently contains certainerrors necessarily resulting from the standard deviation found in theirrespective testing measurements. Moreover, all ranges disclosed hereinare to be understood to encompass any and all sub-ranges subsumedtherein. For example, a range of “less than 10” can include any and allsub-ranges between (and including) the minimum value of zero and themaximum value of 10, that is, any and all sub-ranges having a minimumvalue of equal to or greater than zero and a maximum value of equal toor less than 10, e.g., 1 to 5.

FIG. 1A shows an example tunable EOM comb generator 100 embodied as a1-phase modulator, according to a disclosed embodiment. The tunable EOMcomb generator 100 shown in FIGS. 1A-1C comprises three sub-systemsshown by the dashed lines therein, with the OEO loop 130 and thefrequency locking loop 110 overlapping with both of these sub-systemssharing optical components including a POF shown by example as a highfinesse FPE 116. However, as noted above the POF can also generally beany high finesse resonator, such as a chip-scale micro-ring resonator,which may also eliminate the optical circulator 115 shown in FIG. 1A.

An FPE is known in the art comprises two fixed parallel plates of anoptically transparent medium (i.e. a glass) on which there is a highlyreflective coating (typically a dielectric film) on their insidesurfaces, facing each other. In FPE operation the light beam that entersthe first plate is either reflected off the surface, or transmittedthrough. The light ray then goes through an air gap (ranging from nm'sto cm's) to the next (second) plate. Once there, the ray will either betransmitted or reflected. If reflected the ray will be redirected to thefirst coating, the same event, of transmission or reflection, willoccur. However, if the distance between the two plates of the FPE issuch that constructive interference will occur with a specific opticalwavelength where the round-trip spacing between the plates coincideswith an integer multiple of the wavelength, the other opticalwavelengths will act destructively with other reflections and so onlythe specific optical wavelength required is transmitted by the FPE, thusproviding an output image in a very narrow waveband. The transmittedwaves, all of which are essentially parallel to each other, exit theFPE.

A FPE's finesse can vary greatly depending on its design, for example,an FPE's finesse can be significantly less than 100 or as high as1,000,000. For disclosed EOM comb generators, as described above, whenthe POF comprises an FPE the FPE 116 selected generally has a finessevalue of at least 1,000, such as a finesse value of 10,000 to 100,000.

The frequency locking loop 110 can in one aspect comprise a standardPound-Drever-Hall (PDH) frequency locking loop for stabilizing thefrequency of a laser 101 shown as a CW laser. The laser 101 is generallya narrow linewidth CW laser which can be a narrow linewidthsemiconductor laser or fiber based-laser that are both commerciallyavailable. The laser 101 acts as the optical source that drives thetunable EOM comb generator 100, and can comprise in one specific examplea 1 kHz linewidth fiber laser, such as the Orbits Lightwave ETHERNAL™Erbium-doped fiber amplifiers (EDFA) laser module which provides awavelength of 1,550 nm. The wavelength of the laser 101 selected dependson the application. In theory, any laser wavelength can be used providedall components in the tunable EOM comb generator 100 are compatible atthat wavelength.

The frequency locking loop 110 is for receiving light from the laser 101that is coupled by an optical isolator (ISO) 102 to a first polarizationcontroller (PC1) 103, and then to an intensity modulator (IM) 137 in theOEO loop 130. The light source can be a CW source, or a pulsed lightsource as long as its repetition rate matches the resonator such as anFPE's free spectral range or a harmonic of it. The IM 137 can comprise aMach-Zehnder intensity modulator (MZM). The frequency locking loop 110comprises a frequency shifter shown by example as an acousto-opticmodulator (AOM) 112 for frequency correction, a second polarizationcontroller (PC2) 113, a first phase modulator (PM1) 114, an opticalcirculator 115, and a high finesse FPE 116, that is coupled to anoptical amplifier 131 shown as an EDFA, such as providing a power of +3dBm.

The optical circulator 115 is a passive non-reciprocal three-port deviceas shown, in which an optical signal entering any of its ports istransmitted to the next port in rotation (only). A port in this contextis a point where an external device connects to the optical circulator115. For a three-port optical circulator, a signal applied to port 1 ofthe circulator 115 only comes out of port 2; a signal applied to port 2only comes out of port 3; a signal applied to port 3 only comes out ofport 1, so to within a phase-factor.

PM1 114 generates sidebands, such as about 300 MHz sidebands. Thefrequency locking loop 110 includes a feedback network from an output ofthe optical circulator 115 to the frequency shifter shown as AOM 112,the feedback network including a first photodetector (PD1) 117, anamplifier 118, a frequency mixer 119, a loss pass filter (LPF) 121, afirst controller 122, and a voltage controlled oscillator (VCO) 123. Thefrequency shifter can also comprise a Single Sideband Modulator (SSB).There is a frequency synthesizer 120 shown between the mixer 119 and thePM1 114. When the laser's 101 optical frequency coincides with apassband of the FPE 116, and the sidebands from PM1 114 are reflectedwhich are photodetected by PD1 117 to create an error signal (describedbelow) for the frequency locking electronics of the frequency lockingloop 110.

Regarding the error signal, the error signal is created in the frequencylocking loop 110 by the following:

1. Side bands are created around the laser 101 frequency using the PM1114, which is driven by the frequency synthesizer 120.2. The resulting optical signal (i.e. the laser 101 frequency plus itsPM sidebands) then enters through port 1 of the optical circulator 115to exit port 2 of the optical circulator 115 towards the FPE 116. Lightthat is reflected from the FPE 116 enters port 2 of the opticalcirculator 115 exits port 3, where it is photodetected by PD1 117.3. The electrical signal generated by PD 117 is then mixed with a tappedportion of the electrical signal from the frequency synthesizer 120 thatwas used to create the phase modulation sidebands in step 1, creatingthe error signal.

The controller 122 shown by example as aproportional-integral-derivative (PID) controller uses this error signalto generate an output voltage to drive the VCO 123 which is thensupplied as an electrical frequency to the AOM 112 to shift the opticalfrequency of the laser 101. The signal from the VCO 123 is fed back tothe AOM 112 for shifting the frequency of the throughput light to keepthe light from the laser 101 within the passband of the FPE 116,establishing a lock to stabilize the laser's 101 light frequency.

The frequency synthesizer 120 provide two outputs, one of which isapplied to the PM1 114, while the other output is applied to thefrequency mixer 119. The two outputs can come from the output from asingle frequency synthesizer as shown in FIGS. 1A-1C by splitting asingle output, or the respective frequency outputs can come from twoseparate frequency synthesizers provided they share a common frequencyreference and are phase locked. The mixer 119 only has two inputs and asingle output, where its local oscillator input is driven by the outputfrom the frequency synthesizer 120, while the other mixer 119 input isdriven by the photodetected signal from PD1 117.

The mixing product output from this mixer 119 is what creates the errorsignal that the first controller 122 receives after filtering by the LPF121. The first controller 122 uses this error signal received to createa voltage used to control the output frequency of the VCO 123. Theoutput signal from the VCO 123 after amplification by amplifier 124 isfed back to the AOM 112, shifting the frequency of the throughput lightto keep the laser 101 within the passband of the FPE 116, establishing afrequency lock to stabilize and thus minimize possible otherwise fastfrequency fluctuations.

Due to the generally limited bandwidth of the AOM 112, the CW tone fromthe laser 101 can only for example drift to an offset of ±10 MHz fromthe FPE's 116 passband before the AOM 112 can no longer providesufficient frequency correction, in which case the frequency lock canbecome ineffective. The laser's 101 natural operating frequency candrift beyond these limits due to fluctuations in typical operatingconditions, such as in the temperature. Thus, an optional secondfeedback loop is shown in FIGS. 1A-1C to correct for this slower,long-term frequency drift. This correction is realized by applying anauxiliary output from the first controller 122 to a second controller104 that is also shown by example as PID controller.

The second controller 104 operates using only one input, being theauxiliary error output from the first controller 122. This auxiliaryoutput provides information about how far the output voltage of thefirst controller 122 has drifted from the initial output voltage, andthe second controller 104 acts to adjust the frequency of the laser 101and to minimize this error. When this error value is zero, the firstcontroller 122 is outputting a voltage equal to the initially setvoltage. The second controller 104 outputs a voltage which is applied toa control input (port) on the laser 101, acting to slowly tune thelaser's 101 frequency output to keep it closer to the FPE's 116passband, and thus within the AOM's 112 limited range of frequencycorrection.

The OEO loop 130 comprises an optical power splitter 132 shown as a 3 dBsplitter for splitting an optical signal output by the FPE 116 into afirst optical signal 151 and a second optical signal 152, a second PD(PD2) 133 for generating a first RF signal (RF1 signal) from the firstoptical signal 151, a first tunable phase shifter (PS1) 134 for phaseshifting the first optical signal 151, and a first RF splitter 136 forproviding a second RF signal (RF2 signal) coupled to IM 137 (completingthe OEO loop 130) and a third RF signal (RF3 signal). PS1 134 and otherPS's disclosed herein can be controlled manually (e.g., using a knobthat can be manually turned or twisted to adjust the phase). However,voltage controlled PSs are known that can also be used with anelectrical control system for phase tuning.

Fine adjustment of the PS1 134 being within the OEO loop 130 is used toalign the OEO loop 130 modes with the resonances of the FPE 116,allowing for the oscillator's resonant frequency and thus the generatedoutput RF frequency. RF1, RF2 and RF3 signals all have the samefrequency, which can be any harmonic of the FPE's 116 FSR, which asshown by example herein corresponds to 7.5, 9.0, 10.5, 12 GHz due to thelimited bandwidth of the electrical components used in the OEO loop 130,to be tuned to harmonics of the FPE's 116 FSR, such as in one example a1.5 GHz FSR. The highest achievable resonant frequency is thus generallyonly limited by the bandwidth of the electrical components in the OEOloop 130.

The IM 137 also serves a pulse-carver for the EOM comb 140, generatingthe first set of sidebands around the seed CW tone from the laser 101.The total OEO loop 130 length may on be on the order of only about 15 m.An optional RF amplifier 135 is coupled to an output of PS1 134 thatamplifies the signal, such as to a power of about +24 dBm. The RF3signal is applied via an isolator (ISO) 105 to the optional RF amplifier142 of the EOM comb 140. RF amplifiers can comprise operationamplifiers.

In FIG. 1A the EOM comb 140 includes a single PS and a single PM, shownas PS2 144 and a second PM (PM2) 147. Disclosed PMs can comprise LiNbO₃PMs. The output of the RF amplifier 142 is coupled to an input of thePS2 144, which is coupled to PM2 147. PM2 147 receives another inputfrom an output from a third PC (PC3) 146, that processes the secondoptical signal 152, where PM2 147 provides the single phase output shownin FIG. 1A as the ‘1 phase comb output’.

In FIG. 1B to implement a 2-phase modulator the EOM comb 140 a comprises2 PS and 2 PM, shown as the PS2 144 and PM2 147 in the EOM comb 140 inFIG. 1A, and a second RF splitter 141 for splitting the RF3 signal intoa RF4 signal coupled to PS2 144 then to PM2 147, and an RF5 signalcoupled to a third PS (PS3) 145 then to a third PM (PM3 149). EOM comb140 a is shown having optional RF amplifiers 142, 143 for signalamplification of the RF4 and RF5 signals, respectively. EOM comb 140also includes PC3 146 that processes the second optical signal 152 at aninput to PM2 147, and a fourth PC (PC4) 148 between PM2 147 and PM3 149.An output of the PM3 149 provides the 2-phase comb output generated bythe tunable EO comb generator 100 shown in FIG. 1B as ‘2-phase comboutput’.

Broadband EOM comb generation is achieved by combining the OEO loop's130 optical output 152 and the RF outputs comprising the RF4 and RF5signals in the cascaded PMs comprising PM2 147 and PM3 149. The RF3signal output from the OEO loop 130 is split by splitter 141 into RF4and RF5, with each signal then amplified by RF amplifiers 142, 143, forexample to a level of about +33 dBm, and applied to the PMs 147, 149.Each PM 147, 149 can have a Vπ of 3.6V at 10 GHz and can be capable ofhandling 2 W of RF power. RF PS's 144, 145 are included to adjust timingbetween the RF4 signal applied to the PM 147, and RF5 signal applied to149, for tuning of the comb flatness, bandwidth, and the spectral phase.

In FIG. 1C to implement a tunable EOM comb generator 180 as a 3-phasemodulator the EOM comb 140 b comprises to 3 PS and 3 PMs. Beyond the EOMcomb 140 a shown in FIG. 1B, EOM comb 140 b further comprises a splitter141 a for splitting the received signal into RF5 (shown in FIG. 1B) andRF6 signal which is supplied to a third phase block comprising RFamplifier 143 a, PS4 157 and PM4 158, where PM4 158 receives at an inputthe output from PM3, there is another PC shown as PC5 159 between PM3149 and PM4 158, where PM4 158 provides the 3 phase comb output shown inFIG. 1C.

EXAMPLES

Disclosed aspects are further illustrated by the following specificExamples, which should not be construed as limiting the scope or contentof this Disclosure in any way.

Lab results from the tunable EOM comb generator 150 shown in FIG. 1Bwith the specific components described above demonstrated regenerativelycreated EO combs whose comb teeth spacing was found to be tunable by PSadjustment to PS1 134 to 7.5 GHz, 9 GHz, 10.5 GHz or 12 GHz, with centercomb tooth linewidths on the order of hundreds of Hz. A spectrumanalyzer was used to display these results. Including PMs such as PM2147 and PM3 149 outside of the OEO loop 130 allows for independenttuning and improving of comb flatness and spectral phase for ultrashortpulse generation without affecting oscillation. Linear pulse compressionis used to demonstrate ultrashort pulses with a picosecond-levelautocorrelation pulse widths at a repetition rate of 10.5 GHz.

An enhancement in optical linewidth is evidenced that occurs as a directconsequence of the frequency locking loop 110 frequency-locking thelaser 101 to the FPE 116. FIG. 2A shows heterodyne beat measurements fora CW laser obtained under both frequency locking loop 110 locked (shownas ‘locked’) and conventional free-running (shown as ‘free run”)operation. The comparison shows a noticeable reduction in linewidth whenbeing frequency locked by the frequency locking loop 110, directlycorresponding to a significant reduction in optical linewidth of thefrequency stabilized laser 101.

FIG. 2B shows the heterodyne beat when being frequency locked, plottedwith Lorentzian curves of 450 Hz FWHM (L1) and 200 Hz FWHM (L2) forcomparison. Heterodyne beats were obtained by beating a commerciallyavailable 100 Hz linewidth CW laser. By manually adjusting the OEOloop's 130 RF PS1 134, single-mode OEO operation was achieved atfrequencies of 7.5, 9, 10.5 and 12 GHz, corresponding respectively tothe fifth, sixth, seventh and eighth harmonics of the FPE's 116 FSR.Overlaid electrical spectra of the OEO's 130 RF3 signal output at thesefrequencies are included as shown in FIG. 3A. All electrical spectrawere measured after 20 dB of attenuation. Operation of the OEO loop 130was restricted to these frequencies due to the bandwidth of the X-bandRF components used in this particular experiment.

A close-span spectrum of an RF tone generated by the OEO loop 130operating at 10.5 GHz is shown in FIG. 3B. In this case the generated RFsignal exhibited a spectrally pure tone with a signal to noise ratio(SNR) around 80 dB. These characteristics are typical of RF tonesgenerated for OEO loop 130 operation at all frequencies tested.

Fractional frequency stability was measured on the generated RF tone andthe photodetected EOM comb 140 at an operating frequency 10.5 GHz. Theresult obtained are plotted in FIG. 4. The Allan deviation (a knownmeasure of frequency stability) shown as ‘ADEV’ was measured as low as5×10⁻¹⁰ for τ=0.2 s, corresponding to a frequency stability around 5 Hz.At τ=1 s, the measured Allan deviation was 9×10⁻¹⁰, or a frequencystability better than 10 Hz. Improved frequency stability beyond τ=0.2 shas been shown in a similar system in which the FPE 116 was held undervacuum. To achieve further improved comb flatness and bandwidth when theRF signal is applied to the PMs 147, 149, the phase of the RF signalinput to each PM 147, 149 can be carefully adjusted such that the peakof the sine wave input essentially exactly coincides with the peak ofthe optical pulse carved by the IM 137. This is achieved in this case byprecisely adjusting the phases of PS2 144 and PS3 145 while observingthe output optical spectrum after each PM 147, 149. When the phase isproperly aligned, the number of comblines in the output of the EOM comb140 greatly increases and the optical spectrum obtains it's a furtherimproved flatness.

Amplitude stability of the generated comb teeth output by the EOM comb140 were analyzed by monitoring the optical spectrum of the tunable EOMcomb generator every five minutes for an hour on a spectrum analyzer.The average amplitude is plotted in FIG. 5, with error bars showing thestandard deviation of each comb tooth within 10 dB amplitude deviation.The average standard deviation of the comb tooth amplitude is ±0.22 dB,with a maximum standard deviation of ±0.77 dB.

Optical spectra for disclosed EOM comb generators generated with 7.5, 9,10.5 and 12 GHz spacings are shown in FIGS. 6A-6D. Comb flatness andbandwidth were tuned by adjusting the PSs PS2 144 and PS3 145 each timethe OEO loop's 130 frequency is tuned between different resonances. Thecomb bandwidth is limited by the total accumulated phase modulationindex in the cascade of phase modulators PM2 147 and PM3 149.Degradation of the optical SNR at smaller comb spacings can beattributed to the limited resolution (about 0.01 nm) of the opticalspectrum analyzer.

To generate short optical pulses, an OEO-EOM comb was generated at 10.5GHz and the phase into each PM 147, 149 was carefully adjusted (usingPS2 144 and PS3 145, respectively) to ensure appropriate spectral phase,and thus the frequency chirp, in the output pulses. Application of aproper chirp was verified by sending the output pulses through lengthsof single-mode fiber with anomalous dispersion while measuring theoutput pulse duration with a high speed PD on a 50 GHz digital samplingoscilloscope. By creating pulses which are upchirped, propagation in theanomalously dispersive optical fiber acts to compensate for the linearchirp created by the PMs 147, 149, greatly shortening the temporalduration of the pulses.

Compression of the 10.5 GHz repetition rate OEO-EOM comb pulses wasachieved by incrementally adding a single mode optical fiber (SMF) usingthe SMF-28 from Corning for compression. Intensity autocorrelation ofthe output pulse after 600 m of fiber is included in FIG. 7, showing anautocorrelation pulse width of 2.6 psec (curve 1). Also plotted is theFourier transform limit pulse (curve 2) which was calculated using theoptical spectrum and assuming a flat phase.

While various disclosed embodiments have been described above, it shouldbe understood that they have been presented by way of example only, andnot as a limitation. Numerous changes to the disclosed embodiments canbe made in accordance with the Disclosure herein without departing fromthe spirit or scope of this Disclosure. Thus, the breadth and scope ofthis Disclosure should not be limited by any of the above-describedembodiments. Rather, the scope of this Disclosure should be defined inaccordance with the following claims and their equivalents.

1. A tunable electro-optic modulation (EOM) comb generator, comprising:a frequency locking loop for receiving light from a light source coupledto in sequence an intensity modulator (IM), a frequency shifter, asecond polarization controller (PC2), a first phase modulator (PM1) anda periodic optical filter (POF), a feedback network from an output ofthe PM1 to an input of the frequency shifter including in sequence afirst photodetector (PD1), a frequency mixer, a first controller, avoltage controlled oscillator (VCO), and a frequency synthesizer betweenthe frequency mixer and the PM1; an optoelectronic oscillator (OEO) loopcomprising an optical power splitter for splitting an optical signaloutput by the POF into a first and a second optical signal and a secondPD (PD2) for generating a first RF (RF1) signal from the first opticalsignal, a first tunable phase shifter (PS1) for phase shifting the firstoptical signal, and a first RF splitter for providing a second RF (RF2)signal coupled to the IM and a third RF (RF3) signal, and an EOM combcoupled to receive the RF3 signal comprising a second PS (PS2) coupledto a second PM (PM2) and a third polarization controller (PC3) coupledto process the second optical signal and then provide an output to thePM2, wherein an output of the PM2 provides an output for the EOM combgenerator.
 2. The EOM comb generator of claim 1, wherein the EOM combfurther comprises a second RF splitter for splitting the RF3 signal intoa RF4 signal that is coupled to the PS2 and an RF5 signal that iscoupled to a PS3 that has its output coupled to an input of the PM2. 3.The EOM comb generator of claim 1, wherein the POF comprises aresonator.
 4. The EOM comb generator of claim 1, wherein the POFcomprises a Fabry-Perot etalon (FPE), further comprising a circulatorbetween the PM1 and the FPE.
 5. The EOM comb generator of claim 4,wherein the FPE provides a finesse of at least 10,000.
 6. The EOM combgenerator of claim 1, further comprising a second controller coupled toreceive an auxiliary output from the first controller, the secondcontroller outputting a voltage signal coupled to a control input of thelight source.
 7. The EOM comb generator of claim 1, wherein the lightsource comprises a continuous wave laser.
 8. The EOM comb generator ofclaim 1, wherein the frequency shifter comprises an acousto-opticmodulator (AOM).
 9. A method of tunable electro-optic (EO) combgeneration, comprising: frequency locking an optoelectronic oscillator(OEO) loop comprising RF electrical components including a phase shifter(PS1), a splitter and optical components comprising an intensitymodulator (IM) coupled to receive light from a light source and couplemodulated light to a frequency locking loop including a frequencyshifter, a first phase modulator (PM1), and a periodic optical filter(POF); the POF optically filtering the OEO loop to generate an opticaloutput and the splitter generating RF electrical outputs comprising oneRF output coupled to an input of the IM and another RF output coupled toan EO comb comprising at least a phase modulator; The EO comb combiningthe optical output and the another RF output to generate a broadbandoptical frequency comb output.
 10. The method of claim 9, wherein thePOF comprises a Fabry-Perot etalon (FPE), further comprising adjusting adelay using the PS1 for tuning the broadband optical frequency comboutput to adjust a combline spacing to harmonics of free spectral range(FSR) of the FPE that falls within an electrical bandwidth of the RFelectrical components.
 11. The method of claim 9, wherein the lightsource comprises a laser, and the frequency locking loop includes afirst controller between the POF and the frequency shifter, furthercomprising utilizing a second controller coupled to receive an auxiliaryoutput from the first controller, wherein the second controller outputsa voltage signal coupled to a control input of the laser.
 12. The methodof claim 10, wherein the FPE has a finesse of at least 10,000.